Reading through the new report is an exercise in déjà vu for space policy geeks. It reads very much like the
Exploration Systems Architecture Study (ESAS) of 2005. No big surprise, when one realizes that many of the people who wrote that report are involved in the new one. But more than that, the sense of a previous life stems from the rocket design that has resulted from this effort. It looks remarkably similar to the rocket that resulted from the previous effort, the late and not-so-lamented Ares family of heavy lifters. As you may recall, a key conclusion of the oft-cited
Augustine Committee report was that the existing program of record (Project Constellation, a.k.a. Ares rocket) was unaffordable without infusions of significant quantities of new money.

Did NASA get a big infusion of cash? No. So no one should be surprised that the same people, working under the same assumptions within the same agency and technology base as the Project Constellation people would reach the same conclusions. In fact, most were not surprised. But apparently,
many in the United States Senate did expect a different answer. Or did they?

We now enter the political Hall of Mirrors in which what people say they want isn’t necessarily related to what they really want or don’t want. Let us see if we can chart a path through the maze of motives, desires and statements to fully understand exactly what’s going on. Please stay with me on this until the end; I will try to make things clear.

Seven years ago, we had the
Vision for Space Exploration (VSE), a statement of strategic direction in space. The VSE called for returning Shuttle to flight after the Columbia accident, completing construction of the ISS, the building of a new space transportation system, a return to the Moon (“with the goal of living and working there for increasing periods of time”) and finally, human missions to Mars and “other destinations.” After the VSE was announced, NASA “implemented” it by completing steps 1 and 2. Step 3 was started, outlining an architecture and design for a new human spacecraft and new launch vehicles (the ESAS). We never progressed beyond that, although many departments, universities and international partners dug in and began conducting studies of work and instruments needed to live on the Moon.

It is a fool’s errand to design architectures and new space vehicles if you do not know what your mission is. You
can design and build a space system without an objective but as it must satisfy many different purposes, it tends to not satisfy any of them particularly well. From the beginning, NASA leadership didn’t acquaint itself with why they were tasked with lunar return, even though the VSE founding documents are quite clear on the purpose and activities associated with lunar return. Because of this strategic confusion, it was largely assumed by many that we would do on the Moon what we did 40 years ago – explore, collect samples, and leave as soon as possible (that last activity being particularly favored within the agency). To accommodate this activity, the Ares launch vehicles were designed to conduct a lunar mission with two launches – the Ares I, which would put the crew vehicle in low Earth orbit and the Ares V, which carried all the other pieces. Additionally, NASA never lost sight of its desire for Mars, so Ares V was sized at a payload capacity of 160 tons, overkill for a lunar mission but thought to be the right number for a human Mars mission, staged completely from the surface of the Earth (whether that’s true is another story).

As Ares rocket development costs rose, other pieces of the lunar return architecture were discarded. Eventually, we had a large rocket-building program but its purpose had become diffuse and nebulous (in 2009, the acting Administrator of NASA told Congress in testimony that
he did not know what going to the Moon meant).

Curiously, the
new NASA Authorization Act of 2010 was remarkably specific about the requirements of a new heavy lift vehicle the agency had been directed to build. It was to use Shuttle hardware to “
the extent practicable” and initially carry 70-100 tons but designed such that it could be stretched to a lift capacity of 130 tons. Where did these numbers come from? It’s not clear, but here’s an interesting coincidence: 130 tons was the lift capacity of the old
Saturn V (118,000 kg = 260,000 pounds = 130 tons). NASA has interpreted the new Congressional language as meaning
metric tons (2200 lbs) but the simple language of the law says “tons” (1 ton = 2000 lbs). One might suspect that the calculus was that heavy lift in days of old (Saturn V) meant 130 tons, so that’s what “heavy lift” should be.

In the absence of any specific mission, the payload capacity of your launch vehicle is entirely academic. But this “requirement” has had some serious ramifications. Last summer, a study group at Johnson Space Center released a report (Preliminary Report Regarding NASA's Space Launch System and Multi-Purpose Crew Vehicle, Pursuant to Section 309 of the NASA Authorization Act of 2010 (P.L. 111-267), SSP Study NSTS 60583, dated June 8, 2010) showing how a heavy lift vehicle could be built and flown under the then-current run out budget (any new budget for NASA is pure guesswork at this stage). It resurrects an old concept of replacing the Shuttle orbiter on the existing stack with a payload fairing and engine pod. This configuration, called
Shuttle Side-Mount (updated from the old “Shuttle-C” concept) was not considered by the HEFT study team, but meets the specific language of the new authorization. The advantage of SSM is that, as it is a minimal modification of the existing stack, it uses all of NASA’s existing launch and processing infrastructure – launch pads, mobile crawlers, scaffolding in the VAB and fabrication facilities in Michoud and Utah. SSM initially carries about 80 metric tons (70 (63.3 metric) to 100 (90.7 metric) tons) and can be stretched to meet the 130 ton (118 metric tons) legal requirement with minimal modification (for example, adding 5-segment (instead of 4-segment) Solid Rocket Boosters, 4 Shuttle Main Engines, extended External Tank). So in fact, SSM meets all the technical, budgetary, safety and schedule requirements set out in the NASA Authorization Act of 2010.

So as Oliver Hardy would say, here’s another fine mess we’ve gotten ourselves into. NASA creates an unaffordable architecture (ESAS) to implement the VSE. The response by the new administration is to cancel the VSE and replace it with promises of more distant goals at some nebulous time in the far future. Congress directs the agency to build an HLV anyway, but the vehicle has no mission, so they pull out the specs of the last HLV America flew. NASA responds by saying they can’t do it on the money and schedule specified, even though they themselves
have in hand a report that shows how it can be done. Moreover, the agency still claims it doesn’t know why anyone would want to go to the Moon, despite having been shown repeatedly that
what we do there will create new space faring capability.

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About Paul D. Spudis

Paul D. Spudis is a senior staff scientist at the Lunar and Planetary Institute in Houston, Texas. His website can be found at www.spudislunarresources.com. The opinions expressed here are his own and do not reflect the views of the Smithsonian Institution or his employer.